Glucocorticoids induce the expression of the uteroglobin gene in rabbit foetal lung explants cultured in vitro.

In 27-day-old rabbit foetal lung explants cultured in vitro, the synthesis of the protein uteroglobin decreased progressively during several days of culture. Addition of glucocorticoids to the medium progressively induced the synthesis of uteroglobin in a dose-dependent manner without affecting the synthesis of total proteins. The glucocorticoid-mediated induction of uteroglobin appears mainly due to increased amounts of uteroglobin mRNA and seems to be independent of simultaneous cell proliferation, suggesting a glucocorticoid-triggered differentiation of pre-existing cells. The results suggest a major role of glucocorticoids in the developmental regulation of the uteroglobin gene in the lung.     

Iron homeostasis in the lung

Iron is essential for many aspects of cellular function. However, it also can generate oxygen-based free radicals that result in injury to biological molecules. For this reason, iron acquisition and distribution are tightly regulated. Constant exposure to the atmosphere results in significant exposure of the lungs to catalytically active iron. The lungs have a mechanism for detoxification to prevent associated generation of oxidative stress. Those same proteins that participate in iron uptake in the gut are also employed in the lung, to transport iron intracellularly and sequester it in an inactive form within ferritin. The release of metal is expedited (as transferrin and ferritin) from lung tissue to the respiratory lining fluid for clearance by the mucocilliary pathway or to the reticuloendothelial system for long-term storage. This pathway is likely to be the major method for the control of oxidative stress presented to the respiratory tract.     

Ricin disturbs calcium homeostasis in the rabbit heart

Ricin, a toxic lectin from the castor bean, affects the cardiovascular system. Because calcium is very important in cardiotoxicity and cell intoxication, we studied the effects of ricin pretreatment to rabbits on basal intracellular calcium levels and calcium uptake and release from isolated papillary muscle, microsomes, and mitochondria. An increase in basal intracellular calcium levels was observed. Ricin pretreatment nearly doubled the intracellular-free Ca²⁺ concentration as measured by fura-2 fluorescence microscopy in isolated myocytes (p = 0.002). Ricin did not alter basal calcium efflux in isolated papillary muscles. However, ricin inhibited the NE-induced calcium efflux (expressed as fractional efflux ratios) in papillary muscles from rabbits receiving the minimum lethal dose of ricin at 25–35 minutes (p = 0.002 and 0.003, respectively). Ricin depressed basal calcium uptake into isolated papillary muscles at 5 minutes (mean ± SEM, μmol/g wet weight) (control: 3.68 ± 0.57; ricin: 2.31 ± 0.28, p = 0.045, n = 6). Ricin pretreatment significantly depressed calcium uptake into microsomes (mean ± SEM, μmol/g protein) (control: 9.9 ± 1.9; ricin: 3.1 ± 1.9, p = 0.025, n = 6). Calcium uptake into mitochondria was increased at the beginning (2 minutes, p = 0.048), but not thereafter. Thus, administration of ricin disturbed calcium homeostasis in the rabbit heart, which may be at least partially responsible for altering cardiac function and myocardial cell death. © 1996 John Wiley & Sons, Inc.     

Effect of Osmolality and myo-Inositol Deprivation on the Transport Properties of myo-Inositol in Primary Astrocyte Cultures

myo-Inositol uptake measured in primary astrocyte cultures was saturable in the presence of Na⁺ with a Km of 13–18 M and a Vmax of 9.4 nmoles/mg protein/hour in myo-inositol-fed cells, indicating a high affinity transport system. In myo-inositol-deprived cells, Km was about 53 M with a Vmax of 13.2 nmoles/mg protein/hour. Decreasing osmolality decreased the Vmax to about 1.9 nmoles/mg protein/hour whereas increasing osmolality increased Vmax about 5-fold, while Kms were essentially unchanged in myo-inositol fed cells. In cells deprived of myo-inositol, Vmax decreased in hypotonic medium and increased in hypertonic medium almost 10-fold, but with more than a doubling of the Km regardless of the osmolality. Glucose (25 mM) inhibited myo-inositol uptake 51% whereas the other hexoses used inhibited uptake much less. Our findings indicate that myo-inositol uptake in astrocytes occurs through an efficient carrier-mediated Na⁺-dependent co-transport system that is different from that of glucose and its kinetic properties are affected by myo-inositol availability and osmotic stress.     

Ion transport regulation of lung liquid secretion in foetal lambs.

To test the hypothesis that liquid formation in the foetal lung reflects the balance between Cl- secretion and Na+ absorption by the respiratory tract epithelium, we studied the independent and combined effects of selective ion transport inhibitors on basal production of lung liquid in foetal lambs. We prepared 19 foetal lambs (gestation 125 +/- 4, term = 147 days) with chronic indwelling catheters for subsequent measurement of luminal liquid production over time (JV). Using an impermeant tracer technique, we measured JV before and after tracheal instillation of 2 different inhibitors of ion transport: bumetanide, a Na(+)-K(+)-2Cl- co-transport inhibitor, and amiloride, a Na+ transport inhibitor. In 7 foetuses we sequentially added bumetanide (10(-4) M) and 2 different concentrations of amiloride (10(-6) M, 10(-4) M) to the liquid within the lung lumen. After we gave bumetanide, JV decreased from 12 +/- 4 ml/h to 0 +/- 5 ml/h and subsequently increased during the 2 periods of amiloride exposure (10(-6) M: 6 +/- 5 ml/h; 10(-4) M: 7 +/- 7 ml/h). In 5 control studies we gave bumetanide, followed by only amiloride vehicle. JV for all time periods in the control studies was similar to the experimental group, demonstrating no effect of amiloride. In 5 foetuses we administered the 2 concentrations of amiloride before bumetanide. There was no change in JV with either concentration of amiloride (baseline: 13 +/- 2 ml/h; 10(-6) M amiloride: 15 +/- 5 ml/h; 10(-4) M amiloride: 13 +/- 6 ml/h).(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphatidylinositol-inositol exchange in a rabbit lung

A microsomal fraction prepared from rabbit lung tissue was found to catalyze CDPdiacylglycerol-independent incorporation of [3H]inositol into phosphatidylinositol. This incorporation resulted from CMP-dependent phosphatidylinositol-inositol exchange and did not constitute a net synthesis of phosphatidylinositol. The phosphatidylinositol-inositol exchange activity was distinct from the phospholipid-base exchange enzymes and was specific for inositol. Optimal in vitro phosphatidylinositol-inositol exchange activity was observed at pH 8.5--8.8 and either Mn2+ or Mg2+ was essential for activity. Mercaptoethanol stimulated phosphatidylinositol-inositol exchange and Hg2+ inhibited this activity. In the absence of CMP, no phosphatidylinositol-inositol exchange was observed. CDP (and to a smaller extent CTP) also supported phosphatidylinositol-inositol exchange and this appeared to occur via the generation of CMP during incubations. The apparent Km values of the phosphatidylinositol-inositol exchange enzyme for CMP and inositol were 0.4 mM and 11 microM, respectively. When CDPdiacylglycerol was present at a concentration optimal for CDPdiacylglycerol : inositol transferase activity, CMP-dependent phosphatidylinositol-inositol exchange activity was still observed. However, in the presence of Hg2+ CDPdiacylglycerol inhibited phosphatidylinositol-inositol exchange activity. Several properties of the phosphatidylinositol-inositol exchange enzyme resemble those of CDPdiacylglycerol : inositol transferase, but the two enzymes appear distinct on the basis of different degrees of inhibition by either Ca2+, Hg/+ or heat, and on the basis of different changes in activity during lung development.     

myo-Inositol Transport in Mouse Astroglia-Rich Primary Cultures

Uptake of radiolabeled myo-inositol was studied in astroglia-rich primary cultures derived from neonatal mouse brains. The uptake was saturable in the presence of Na+ with a Km of 25 microM and a Vmax of 60 pmol.min-1.(mg protein)-1, suggesting a high-affinity transport system for myo-inositol in astroglial cells. In addition, a Na(+)-independent, nonsaturable component was found. Carrier-mediated uptake was not inhibited by cytochalasin B (50 microM), but was reduced by depolarizing concentrations of K+ and, to different extents, in the presence of phloretin, ouabain, or amiloride (1 mM each). scyllo-Inositol, glucose, and galactose also reduced myo-inositol uptake; inhibition by the two hexoses was not reversed in the presence of 0.4 mM sorbinil. On the other hand, uptake of 2-deoxyglucose was not inhibited by high concentrations of myo-inositol. Preincubation of the cells with glucose-free or inositol-free medium stimulated uptake of myo-inositol and preincubation with 25 mM glucose in the presence of 0.4 mM sorbinil had no effect on the rate of uptake. The results suggest that myo-inositol is taken up into the astroglial cells by a transport mechanism that is distinct from that of glucose and probably is an active one. Sorbitol pathway activity does not interfere with myo-inositol uptake.     

Disruption of iron homeostasis and lung disease

As a result of a direct exchange with the external environment, the lungs are exposed to both iron and agents with a capacity to disrupt the homeostasis of this metal (e.g. particles). An increased availability of catalytically reactive iron can result from these exposures and, by generating an oxidative stress, this metal can contribute to tissue injury. By importing this Fe³⁺ into cells for storage in a chemically less reactive form, the lower respiratory tract demonstrates an ability to mitigate both the oxidative stress presented by iron and its potential for tissue injury. This means that detoxification is accomplished by chemical reduction to Fe²⁺ (e.g. by duodenal cytochrome b and other ferrireductases), iron import (e.g. by divalent metal transporter 1 and other transporters), and storage in ferritin. The metal can subsequently be exported from the cell (e.g. by ferroportin 1) in a less reactive state relative to that initially imported. Iron is then transported out of the lung via the mucociliary pathway or blood and lymphatic pathways to the reticuloendothelial system for long term storage. This coordinated handling of iron in the lung appears to be disrupted in several acute diseases on the lung including infections, acute respiratory distress syndrome, transfusion-related acute lung injury, and ischemia–reperfusion. Exposures to bleomycin, dusts and fibers, and paraquat similarly alter iron homeostasis in the lung to affect an oxidative stress. Finally, iron homeostasis is disrupted in numerous chronic lung diseases including pulmonary alveolar proteinosis, transplantation, cigarette smoking, and cystic fibrosis.     

Glycolysis is not required for fluid homeostasis in isolated rabbit lungs

We investigated whether glycolysis was necessary to maintain the integrity of vascular endothelial and alveolar epithelial barriers in continually weighed isolated rabbit lungs. Lungs were perfused with a cell-free buffered salt solution, and glycolysis was inhibited with a glucose analogue (alpha-methyl glucoside, alpha-MG) or one of two glycolysis inhibitors (iodoacetic acid, IAA, or NaF). Fluid filtration rates (FFR's, the change in lung weight/time) in response to a 7.5-min zone 3 hydrostatic stress (pulmonary arterial and venous pressures raised from 8 to 15 cmH2O, alveolar pressure kept constant at 4 cm on the deflation limb) were repeatedly measured for 120 min after which the lungs were lavaged. The total protein concentration was measured in the bronchoalveolar lavage fluid (BALP). Lactate production was measured to verify inhibition of glycolysis. Lower concentrations of IAA and alpha-MG eliminated lactate production but did not affect FFR or BALP. NaF also had no effect on the FFR or BALP. Only high concentrations of IAA increased FFR and BALP, seemingly by causing nonspecific membrane injury that was unrelated to its specific effects on glycolysis. The glycolytic pathway for energy production is not necessary to maintain the integrity of the pulmonary endothelial-epithelial barrier.